Tamoxifen Directly Interacts with the Dopamine Transporter.

The selective estrogen receptor modulator tamoxifen increases extracellular dopamine in vivo and acts as a neuroprotectant in models of dopamine neurotoxicity. We investigated the effect of tamoxifen on dopamine transporter (DAT)-mediated dopamine uptake, dopamine efflux, and [3H]WIN 35,428 [(-)-2-ß-carbomethoxy-3-ß-(4-fluorophenyl)tropane] binding in rat striatal tissue. Tamoxifen dose-dependently blocked dopamine uptake (54% reduction at 10 µM) and amphetamine-stimulated efflux (59% reduction at 10 µM) in synaptosomes. It also produced a small but significant reduction in [3H]WIN 35,428 binding in striatal membranes, indicating a weak interaction with the substrate binding site in the DAT. Biotinylation and cysteine accessibility studies indicated that tamoxifen stabilizes the outward-facing conformation of the DAT in a cocaine-like manner and does not affect surface expression of the DAT. Additional studies with mutant DAT constructs D476A and I159A suggested a direct interaction between tamoxifen and a secondary substrate binding site of the transporter. Locomotor studies revealed that tamoxifen attenuates amphetamine-stimulated hyperactivity in rats but has no depressant or stimulant activity in the absence of amphetamine. These results suggest a complex mechanism of action for tamoxifen as a regulator of the DAT. Due to its effectiveness against amphetamine actions and its central nervous system permeant activity, the tamoxifen structure represents an excellent starting point for a structure-based drug-design program to develop a pharmacological therapeutic for psychostimulant abuse.

Latch and trigger role for R445 in DAT transport explains molecular basis of DTDS.

A recent study reports on five different mutations as sources of dopamine transporter (DAT) deficiency syndrome (DTDS). One of these mutations, R445C, is believed to be located on the intracellular side of DAT distal to the primary (S1) or secondary (S2) sites to which substrate binding is understood to occur. Thus, the molecular mechanism by which the R445C mutation results in DAT transport deficiency has eluded explanation. However, the recently reported X-ray structures of the endogenous amine transporters for dDAT and hSERT revealed the presence of a putative salt bridge between R445 and E428 suggesting a possible mechanism. To evaluate whether the R445C effect is a result of a salt bridge interaction, the mutants R445E, E428R, and the double mutant E428R/R445E were generated. The single mutants R445E and E428R displayed loss of binding and transport properties of the substrate [3H]DA and inhibitor [3H]CFT at the cell surface while the double mutant E428R/R445E, although nonfunctional, restored [3H]DA and [3H]CFT binding affinity to that of WT. Structure based analyses of these results led to a model wherein R445 plays a dual role in normal DAT function. R445 acts as a component of a latch in its formation of a salt bridge with E428 which holds the primary substrate binding site (S1) in place and helps enforce the inward closed protein state. When this salt bridge is broken, R445 acts as a trigger which disrupts a local polar network and leads to the release of the N-terminus from its position inducing the inward closed state to one allowing the inward open state. In this manner, both the loss of binding and transport properties of the R445C variant are explained.

Effects of diet and insulin on dopamine transporter activity and expression in rat caudate-putamen, nucleus accumbens, and midbrain.

Food restriction (FR) and obesogenic (OB) diets are known to alter brain dopamine transmission and exert opposite modulatory effects on behavioral responsiveness to psychostimulant drugs of abuse. Mechanisms underlying these diet effects are not fully understood. In this study, we examined diet effects on expression and function of the dopamine transporter (DAT) in caudate-putamen (CPu), nucleus accumbens (NAc), and midbrain regions. Dopamine (DA) uptake by CPu, NAc or midbrain synapto(neuro)somes was measured in vitro with rotating disk electrode voltammetry or with [3 H]DA uptake and was found to correlate with DAT surface expression, assessed by maximal [3 H](-)-2-ß-carbomethoxy-3-ß-(4-fluorophenyl)tropane binding and surface biotinylation assays. FR and OB diets were both found to decrease DAT activity in CPu with a corresponding decrease in surface expression but had no effects in the NAc and midbrain. Diet treatments also affected sensitivity to insulin-induced enhancement of DA uptake, with FR producing an increase in CPu and NAc, likely mediated by an observed increase in insulin receptor expression, and OB producing a decrease in NAc. The increased expression of insulin receptor in NAc of FR rats was accompanied by increased DA D2 receptor expression, and the decreased DAT expression and function in CPu of OB rats was accompanied by decreased DA D2 receptor expression. These results are discussed as partial mechanistic underpinnings of diet-induced adaptations that contribute to altered behavioral sensitivity to psychostimulants that target the DAT.

Food restriction induces synaptic incorporation of calcium-permeable AMPA receptors in nucleus accumbens.

Chronic food restriction potentiates behavioral and cellular responses to drugs of abuse and D-1 dopamine receptor agonists administered systemically or locally in the nucleus accumbens (NAc). However, the alterations in NAc synaptic transmission underlying these effects are incompletely understood. AMPA receptor trafficking is a major mechanism for regulating synaptic strength, and previous studies have shown that both sucrose and d-amphetamine rapidly alter the abundance of AMPA receptor subunits in the NAc postsynaptic density (PSD) in a manner that differs between food-restricted and ad libitum fed rats. In this study we examined whether food restriction, in the absence of reward stimulus challenge, alters AMPAR subunit abundance in the NAc PSD. Food restriction was found to increase surface expression and, specifically, PSD abundance, of GluA1 but not GluA2, suggesting synaptic incorporation of GluA2-lacking Ca2+-permeable AMPARs (CP-AMPARs). Naspm, an antagonist of CP-AMPARs, decreased the amplitude of evoked EPSCs in NAc shell, and blocked the enhanced locomotor response to local microinjection of the D-1 receptor agonist, SKF-82958, in food-restricted, but not ad libitum fed, subjects. Although microinjection of the D-2 receptor agonist, quinpirole, also induced greater locomotor activation in food-restricted than ad libitum fed rats, this effect was not decreased by Naspm. Taken together, the present findings are consistent with the synaptic incorporation of CP-AMPARs in D-1 receptor-expressing medium spiny neurons in NAc as a mechanistic underpinning of the enhanced responsiveness of food-restricted rats to natural rewards and drugs of abuse.

Dopamine transporter oligomerization: impact of combining protomers with differential cocaine analog binding affinities.

Previous studies point to quaternary assembly of dopamine transporters (DATs) in oligomers. However, it is not clear whether the protomers function independently in the oligomer. Is each protomer an entirely separate unit that takes up dopamine and is inhibited by drugs known to block DAT function? In this work, human embryonic kidney 293 cells were co-transfected with DAT constructs possessing differential binding affinities for the phenyltropane cocaine analog, [³H]WIN35,428. It was assessed whether the binding properties in co-expressing cells capable of forming hetero-oligomers differ from those in preparations obtained from mixed singly transfected cells where such oligomers cannot occur. A method is described that replaces laborious 'mixing' experiments with an in silico method predicting binding parameters from those observed for the singly expressed constructs. Among five pairs of constructs tested, statistically significant interactions were found between protomers of wild-type (WT) and D313N, WT and D345N, and WT and D436N. Compared with predicted Kd values of [³H]WIN35,428 binding to the non-interacting pairs, the observed affinity of the former pair was increased 1.7 fold while the latter two were reduced 2.2 and 4.1 fold, respectively. This is the first report of an influence of protomer composition on the properties of a DAT inhibitor, indicating cooperativity within the oligomer. The dopamine transporter (DAT) can exist as an oligomer but it is unknown whether the protomers function independently. The present results indicate that protomers that are superpotent or deficient in cocaine analog binding can confer enhanced or reduced potency to the oligomer, respectively. In this respect, positive or negative cooperativity is revealed in the DAT oligomer.

Microstructural mapping of dentate gyrus pathology in Alzheimer's disease: A 16.4 Tesla MRI study.

The dentate gyrus (DG) is an integral portion of the hippocampal formation, and it is composed of three layers. Quantitative magnetic resonance (MR) imaging has the capability to map brain tissue microstructural properties which can be exploited to investigate neurodegeneration in Alzheimer's disease (AD). However, assessing subtle pathological changes within layers requires high resolution imaging and histological validation. In this study, we utilized a 16.4 Tesla scanner to acquire ex vivo multi-parameter quantitative MRI measures in human specimens across the layers of the DG. Using quantitative diffusion tensor imaging (DTI) and multi-parameter MR measurements acquired from AD (N = 4) and cognitively normal control (N = 6) tissues, we performed correlation analyses with histological measurements. Here, we found that quantitative MRI measures were significantly correlated with neurofilament and phosphorylated Tau density, suggesting sensitivity to layer-specific changes in the DG of AD tissues.

Importance of cholesterol in dopamine transporter function.

The conformation and function of the dopamine transporter (DAT) can be affected by manipulating membrane cholesterol, yet there is no agreement as to the impact of cholesterol on the activity of lipid-raft localized DATs compared with non-raft DATs. Given the paucity of information regarding the impact of cholesterol on substrate efflux by the DAT, this study explores its influence on the kinetics of DAT-mediated DA efflux induced by dextroamphetamine, as measured by rotating disk electrode voltammetry (RDEV). Treatment with methyl-ß-cyclodextrin (mßCD), which effectively depletes total membrane cholesterol--uniformly affecting cholesterol-DAT interactions in both raft and non-raft membrane domains--reduced both DA uptake and efflux rate. In contrast, disruption of raft-localized DAT by cholesterol chelation with nystatin had no effect, arguing against a vital role for raft-localized DAT in substrate uptake or efflux. Supranormal repletion of cholesterol-depleted cells with the analog desmosterol, a non-raft promoting sterol, was as effective as cholesterol itself in restoring transport rates. Further studies with Zn(2+) and the conformationally biased W84L DAT mutant supported the idea that cholesterol is important for maintaining the outward-facing DAT with normal rates of conformational interconversions. Collectively, these results point to a role for direct cholesterol-DAT interactions in regulating DAT function.

Neuropathological effects of chronically implanted, intracortical microelectrodes in a tetraplegic patient.

Objective.Intracortical microelectrode arrays (MEA) can be used as part of a brain-machine interface system to provide sensory feedback control of an artificial limb to assist persons with tetraplegia. Variability in functionality of electrodes has been reported but few studies in humans have examined the impact of chronic brain tissue responses revealed postmortem on electrode performancein vivo. Approach.In a tetraplegic man, recording MEAs were implanted into the anterior intraparietal area and Brodmann's area 5 (BA5) of the posterior parietal cortex and a recording and stimulation array was implanted in BA1 of the primary somatosensory cortex (S1). The participant expired from unrelated causes seven months after MEA implantation. The underlying tissue of two of the three devices was processed for histology and electrophysiological recordings were assessed.Main results.Recordings of neuronal activity were obtained from all three MEAs despite meningeal encapsulation. However, the S1 array had a greater encapsulation, yielded lower signal quality than the other arrays and failed to elicit somatosensory percepts with electrical stimulation. Histological examination of tissues underlying S1 and BA5 implant sites revealed localized leptomeningeal proliferation and fibrosis, lymphocytic infiltrates, astrogliosis, and foreign body reaction around the electrodes. The BA5 recording site showed focal cerebral microhemorrhages and leptomeningeal vascular ectasia. The S1 site showed focal tissue damage including vascular recanalization, neuronal loss, and extensive subcortical white matter necrosis. The tissue response at the S1 site included hemorrhagic-induced injury suggesting a likely mechanism for reduced function of the S1 implant.Significance.Our findings are similar to those from animal studies with chronic intracortical implants and suggest that vascular disruption and microhemorrhage during device implantation are important contributors to overall array and individual electrode performance and should be a topic for future device development to mitigate tissue responses. Neurosurgical considerations are also discussed.

Behavioral, biological, and chemical perspectives on atypical agents targeting the dopamine transporter.

BACKGROUND: Treatment of stimulant-use disorders remains a formidable challenge, and the dopamine transporter (DAT) remains a potential target for antagonist or agonist-like substitution therapies. METHODS: This review focuses on DAT ligands, such as benztropine, GBR 12909, modafinil, and DAT substrates derived from phenethylamine or cathinone that have atypical DAT-inhibitor effects, either in vitro or in vivo. The compounds are described from a molecular mechanistic, behavioral, and medicinal-chemical perspective. RESULTS: Possible mechanisms for atypicality at the molecular level can be deduced from the conformational cycle for substrate translocation. For each conformation, a crystal structure of a bacterial homolog is available, with a possible role of cholesterol, which is also present in the crystal of Drosophila DAT. Although there is a direct relationship between behavioral potencies of most DAT inhibitors and their DAT affinities, a number of compounds bind to the DAT and inhibit dopamine uptake but do not share cocaine-like effects. Such atypical behavior, depending on the compound, may be related to slow DAT association, combined sigma-receptor actions, or bias for cytosol-facing DAT. Some structures are sterically small enough to serve as DAT substrates but large enough to also inhibit transport. Such compounds may display partial DA releasing effects, and may be combined with release or uptake inhibition at other monoamine transporters. CONCLUSIONS: Mechanisms of atypical DAT inhibitors may serve as targets for the development of treatments for stimulant abuse. These mechanisms are novel and their further exploration may produce compounds with unique therapeutic potential as treatments for stimulant abuse.

Insulin enhances striatal dopamine release by activating cholinergic interneurons and thereby signals reward.

Insulin activates insulin receptors (InsRs) in the hypothalamus to signal satiety after a meal. However, the rising incidence of obesity, which results in chronically elevated insulin levels, implies that insulin may also act in brain centres that regulate motivation and reward. We report here that insulin can amplify action potential-dependent dopamine (DA) release in the nucleus accumbens (NAc) and caudate-putamen through an indirect mechanism that involves striatal cholinergic interneurons that express InsRs. Furthermore, two different chronic diet manipulations in rats, food restriction (FR) and an obesogenic (OB) diet, oppositely alter the sensitivity of striatal DA release to insulin, with enhanced responsiveness in FR, but loss of responsiveness in OB. Behavioural studies show that intact insulin levels in the NAc shell are necessary for acquisition of preference for the flavour of a paired glucose solution. Together, these data imply that striatal insulin signalling enhances DA release to influence food choices.

A novel bioassay for detecting GPCR heterodimerization: transactivation of beta 2 adrenergic receptor by bradykinin receptor.

Many G-protein-coupled receptors (GPCRs) have been shown to form heteromeric complexes primarily by biochemical methods, including competitive radioligand binding assays or measurements of changes in second-messenger concentration in lysed cells. These results are often cell line specific, and the expression of other cell surface proteins makes it difficult to detect potential functional consequences of GPCR interaction. Here, 2-electrode voltage clamping in Xenopus oocytes was used as a bioassay to explore heterodimerization of bradykinin type 2 receptor (Bk2R) and beta 2 adrenergic receptor (beta(2)AR), using chloride channels as outputs for receptor activation. The data show for the first time that these 2 receptors heterodimerize with functional consequences. Stimulation with bradykinin induced activation of Galphaq- and transactivation of Galphas-coupled pathways in oocytes expressing Bk2R and beta(2)AR. To corroborate these data, potential receptor interaction was examined in PC12 cells, a cell line that endogenously expresses both receptors, and confirmed that stimulation with bradykinin transactivates beta(2)AR. In both oocytes and PC12 cells, transactivation was ablated by Bk2R or beta(2)AR inverse agonists, suggesting that transactivation occurred directly through both receptors. This is the first evidence of Bk2R/beta(2)AR physical interaction, forming a functional heterodimer. The oocyte system may prove highly useful for exploration of GPCR heterodimerization and the functional consequences thereof.

Differential role of beta-arrestin ubiquitination in agonist-promoted down-regulation of M1 vs M2 muscarinic acetylcholine receptors.

BACKGROUND: Sustained agonist-promoted ubiquitination of beta-arrestin has been correlated with increased stability of the GPCR - beta-arrestin complex. Moreover, abrogation of beta-arrestin ubiquitination has been reported to inhibit receptor internalization with minimal effects on receptor degradation. RESULTS: Herein we report that agonist activation of M1 mAChRs produces a sustained beta-arrestin ubiquitination but no stable co-localization with beta-arrestin. In contrast, sustained ubiquitination of beta-arrestin by activation of M2 mAChRs does result in stable co-localization between the M2 mAChR and beta-arrestin. Internalization of receptors was unaffected by proteasome inhibitors, but down-regulation was significantly reduced, suggesting a role for the ubiquitination machinery in promoting down-regulation of the receptors. Given the ubiquitination status of beta-arrestin following agonist treatment, we sought to determine the effects of beta-arrestin ubiquitination on M1 and M2 mAChR down-regulation. A constitutively ubiquitinated beta-arrestin 2 chimera in which ubiquitin is fused to the C-terminus of beta-arrestin 2 (YFP-beta-arrestin 2-Ub) significantly increased agonist-promoted down-regulation of both M1 and M2 mAChRs, with the effect substantially higher on the M2 mAChR. Based on this observation, we were interested in examining the effects of disruption of potential ubiquitination sites in the beta-arrestin sequence on receptor down-regulation. Agonist-promoted internalization of the M2 mAChR was not affected by expression of beta-arrestin lysine mutants lacking putative ubiquitination sites, beta-arrestin 2K18R, K107R, K108R, K207R, K296R, while down-regulation and stable co-localiztion of the receptor with this beta-arrestin lysine mutant were significantly reduced. Interestingly, expression of beta-arrestin 2K18R, K107R, K108R, K207R, K296R increased the agonist-promoted down-regulation of the M1 mAChR but did not result in a stable co-localiztion of the receptor with this beta-arrestin lysine mutant. CONCLUSION: These findings indicate that ubiquitination of beta-arrestin has a distinct role in the differential trafficking and degradation of M1 and M2 mAChRs.

Agonist mediated internalization of M2 mAChR is beta-arrestin-dependent.

BACKGROUND: Muscarinic acetylcholine receptors (mAChRs) undergo agonist-promoted internalization, but evidence suggesting that the mechanism of internalization is beta-arrestin dependent has been contradictory and unclear. Previous studies using heterologous over-expression of wild type or dominant-negative forms of beta-arrestins have reported that agonist-promoted internalization of M2 mAChRs is a beta-arrestin- and clathrin-independent phenomenon. In order to circumvent the complications associated with the presence of endogenous beta-arrestin that may have existed in these earlier studies, we examined agonist-promoted internalization of the M2 mAChR in mouse embryonic fibroblasts (MEFs) derived from beta-arrestin knockout mice that lack expression of either one or both isoforms of beta-arrestin (beta-arrestin 1 and 2). RESULTS: In wild type MEF cells transiently expressing M2 mAChRs, 40% of surface M2 mAChRs underwent internalization and sorted into intracellular compartments following agonist stimulation. In contrast, M2 mAChRs failed to undergo internalization and sorting into intracellular compartments in MEF beta-arrestin double knockout cells following agonist stimulation. In double knockout cells, expression of either beta-arrestin 1 or 2 isoforms resulted in rescue of agonist-promoted internalization. Stimulation of M2 mAChRs led to a stable co-localization with GFP-tagged beta-arrestin within endocytic structures in multiple cell lines; the compartment to which beta-arrestin localized was determined to be the early endosome. Agonist-promoted internalization of M2 mAChRs was moderately rescued in MEF beta-arrestin 1 and 2 double knockout cells expressing exogenous arrestin mutants that were selectively defective in interactions with clathrin (beta-arrestin 2 DeltaLIELD), AP-2 (beta-arrestin 2-F391A), or both clathrin/AP-2. Expression of a truncated carboxy-terminal region of beta-arrestin 1 (319-418) completely abrogated agonist-promoted internalization of M2 mAChRs in wild type MEF cells. CONCLUSION: In summary, this study demonstrates that agonist-promoted internalization of M2 mAChRs is beta-arrestin- and clathrin-dependent, and that the receptor stably co-localizes with beta-arrestin in early endosomal vesicles.

A requirement for membrane cholesterol in the beta-arrestin- and clathrin-dependent endocytosis of LPA1 lysophosphatidic acid receptors.

Lysophosphatidic acid (LPA) stimulates heterotrimeric G protein signaling by activating three closely related receptors, termed LPA(1), LPA(2) and LPA(3). Here we show that in addition to promoting LPA(1) signaling, membrane cholesterol is essential for the association of LPA(1) with beta-arrestin, which leads to signal attenuation and clathrin-dependent endocytosis of LPA(1). Reduction of clathrin heavy chain expression, using small interfering RNAs, inhibited LPA(1) endocytosis. LPA(1) endocytosis was also inhibited in beta-arrestin 1 and 2-null mouse embryo fibroblasts (beta-arrestin 1/2 KO MEFs), but was restored upon re-expression of wild-type beta-arrestin 2. beta-arrestin attenuates LPA signaling as LPA(1)-dependent phosphoinositide hydrolysis was significantly elevated in beta-arrestin 1/2 KO MEFs and was reduced to wild-type levels upon re-expression of wild-type beta-arrestin. Interestingly, extraction of membrane cholesterol with methyl-beta-cyclodextrin inhibited LPA(1) signaling, beta-arrestin membrane recruitment and LPA(1) endocytosis. Cholesterol repletion restored all of these functions. However, neither the stimulation of phosphoinositide hydrolysis by the M(1) acetylcholine receptor nor its endocytosis was affected by cholesterol extraction. LPA treatment increased the detergent resistance of LPA(1) and this was inhibited by cholesterol extraction, suggesting that LPA(1) localizes to detergent-resistant membranes upon ligand stimulation. These data indicate that although LPA(1) is internalized by clathrin- and beta-arrestin dependent endocytosis, membrane cholesterol is critical for LPA(1) signaling, membrane recruitment of beta-arrestins and LPA(1) endocytosis.